The invention relates to a liquid lens (1) with an adjustable optical power comprising at least the following components: a lens volume (VL) with a first transparent liquid (L1) arranged between a first transparent membrane (21) and a second transparent membrane (22) opposite the first membrane (21), wherein the first membrane (21) has a first side (21-1) facing outwards the lens volume (VL) and a second side (21-2) facing in the opposite direction particularly toward the lens volume (VL), wherein the second membrane (22) has a first side (22-1) facing toward the lens volume (VL) and a second side (22-2) facing in the opposite direction particularly outward the lens volume (VL), a lens shaping element (3) arranged on the first membrane (21), the lens shaping element (3) having a circumferential aperture (3a) defining a lens area (21a) of the first membrane (21) having an adjustable curvature, a rigid transparent window element (5) connected to the second membrane (22) covering a window portion (22a) of the second membrane (22), wherein the window element (5) is circumferentially surrounded by a free portion of the second membrane, such that the window element (5) can move relatively to the lens shaping element (3) thereby bending the free portion (22b) of the second membrane (22) and adjusting a liquid pressure in the lens volume (VL), such that a curvature of the first membrane (21) in the lens area (21a) and therefore the optical power of the lens (1) is adjusted.

An optically powered system for rapid, focused heating and melting of water ice. The optical wavelength is chosen to fall in a range where transmissivity through liquid water is higher than through ice. An alternative embodiment of the invention further comprises a length of fiber optic tether between source and output to allow for motion of the melt head. A further embodiment includes probing the ice using various sensing modalities exploiting the presence of the fiber in the ice, searching for biomarkers and characterizing the radiation/light environment for subsurface habitability, including photosynthetic potential and radiation environment as a source for energy.

An imaging lens includes a lens element, a light blocking sheet, and a lens barrel accommodating the lens element and the light blocking sheet. The light blocking sheet includes a first object-side surface, a first image-side surface, a first inner ring surface, a first microstructure, and a first nanostructure layer. The first image-side surface is opposite to the first object-side surface. The first inner ring surface is located between the first object-side surface and the first image-side surface and defines a first light passage opening. The first microstructure is disposed on the first object-side surface or the first image-side surface. The first microstructure has a plurality of protrusions. The first nanostructure layer is disposed on the first inner ring surface. The first nanostructure layer has a plurality of ridge-like protrusions extending non-directionally.

A lens module includes a lens barrel in which a plurality of lenses are disposed, and a lens holder to which the lens barrel is coupled, wherein the lens holder includes a fastening portion fastening the lens barrel, the lens barrel includes a fastening blade coupled to the fastening portion of the lens holder, and the fastening portion includes a stepped portion preventing rotation in a direction, opposite to a direction in which the fastening blade rotates for fastening.

The present invention relates to a method, and an arrangement for attaching a lens to a lens holder. The method comprises: arranging a fixing arc of a fixing part around a compressible retainer of the lens holder, inserting an attachment portion of the lens into the compressible retainer, and reducing a radius of curvature of the fixing arc, such that the compressible retainer of the lens holder is compressed around the attachment portion, thereby attaching the lens to the lens holder.

An optical component fixing structure includes a bearer and at least two or more clamping pieces. The bearer has an accommodating opening, at least two or more sliding trenches and at least two or more protuberances. The protuberance is disposed in the sliding trench. After the clamping piece is moved into the sliding trench, the protuberance is engaged with the retaining hole and at least one of the two sidewalls covers portion of the accommodating opening to fit with the bearer to fix a lens in the accommodating opening. The invention provides a projector using the optical component fixing structure. The projector including a body, and a light source system, the optical component fixing structure, a light valve and a projecting lens are accommodated and fixed in the body.

SMA actuators and related methods are described. One embodiment of an actuator includes a base; a plurality of buckle arms; and at least a first shape memory alloy wire coupled with a pair of buckle arms of the plurality of buckle arms. Another embodiment of an actuator includes a base and at least one bimorph actuator including a shape memory alloy material. The bimorph actuator attached to the base.

An assembly for fixing an optical element in a manner that decouples the optical element from mechanical stresses and thermal strains while providing freedom to facilitate alignment of the optical element, and while also eliminating polymers that can cause contamination problems including a mount configured for attachment to an optical system; a plurality of flexible metal members, each flexible member having a first end affixed to or integrally extending from the mount, and a free end defining a bearing surface for supporting an optical element; and an inorganic adhesive joining a surface of the optical member to the bearing surface.

The present disclosure provides a lens assembly, including: a lens barrel; a lens group with an optical axis accommodated in the lens barrel; a pressure ring arranged on an image side of the lens group and abutting against the lens group; and an optical filter abutting the pressure ring; where the pressure ring includes a first outer wall and an adhesive storage groove connected to the first outer wall and close to the image side; the lens assembly further comprises an adhering part, where the optical filter and the inner wall are arranged to space apart from each other to form an adhesive filling channel, and the adhering part fills the adhesive filling channel and is connected to the adhesive storage groove, the platform part, the inner wall and the optical filter. Compared with the related art, the above-mentioned lens assembly has a large overall thrust and good reliability.

Systems and methods according to one or more embodiments are provided for annealing a chalcogenide lens at an elevated temperature to accelerate release of internal stress within the chalcogenide lens caused during a molding process that formed the chalcogenide lens. In particular, the annealing process includes gradually heating the chalcogenide lens to a dwell temperature, maintaining the chalcogenide lens at the dwell temperature for a predetermined period of time, and gradually cooling the chalcogenide lens from the dwell temperature. The annealing process stabilizes the shape, the effective focal length, and/or the modulation transfer function of the chalcogenide lens. Associated optical assemblies and infrared imaging devices are also described.